Light Confinement by Local Index Tailoring in Inhomogeneous Dielectrics
The engineering of light confinement is a topic with a long history in optics and with significant implications for the control of light‐matter interaction. In inhomogeneous and disordered media, however, multiple scattering prevents the application of conventional approaches for the design of light...
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Veröffentlicht in: | Laser & photonics reviews 2021-09, Vol.15 (9), p.n/a |
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Format: | Artikel |
Sprache: | eng |
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Zusammenfassung: | The engineering of light confinement is a topic with a long history in optics and with significant implications for the control of light‐matter interaction. In inhomogeneous and disordered media, however, multiple scattering prevents the application of conventional approaches for the design of light fields with desired properties. This is because any local change to such a medium typically affects these fields in a non‐local and complicated fashion. Here, we present a theoretical methodology for tailoring an inhomogeneous 1D Hermitian dielectric index distribution that allows us to control the intensity profile of an incoming light field purely locally, that is, with little or no influence on the field profile outside of a designated region of interest. Strongly increasing or decreasing the light's intensity at arbitrary positions inside the medium thereby becomes possible without, in fact, changing the external reflectance or transmittance. These local modifications of the medium can thus be made undetectable to far field measurements. We apply this approach to locally control the confinement of light inside 1D materials with inhomogeneous continuous refractive index profiles and extend it to multilayer films as well as to chains of coupled micro‐resonators.
In inhomogeneous media, any local change of the dielectric distribution typically affects the propagating light fields in a non‐local and complicated way. Here, a method for producing local modifications of an inhomogeneous dielectric medium is described, which leaves the electric field outside of the modified region unchanged—a technique that is used for strongly confining light at targeted locations. |
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ISSN: | 1863-8880 1863-8899 |
DOI: | 10.1002/lpor.202100115 |